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What is the chemical structure of 2-methyl-octahydropyrrolo (3,4-c) pyridine?
2-Methyl-octahydropyrrolo (3,4-c) pyridine, one of the organic compounds. Its chemical structure is quite delicate, composed of a core bicyclic system. In the bicyclic system, one ring is a pyrrole ring and the other ring is a pyridine ring, and the two are fused to form a unique structure.
In terms of its specific structure, "octahydro" indicates that some of the double bonds in the bicyclic system have been hydrogenated, so that the carbon atoms in the ring are connected by a single bond, showing a saturated state. This saturated structure endows the compound with certain stability and unique physical and chemical properties.
"2-methyl" indicates that a methyl group is connected at a specific position (numbered 2) of the dicyclo structure. The introduction of methyl groups affects the spatial structure and electron cloud distribution of the compound, which in turn affects its physical properties, such as boiling point, melting point, etc., and also changes its chemical activity, playing an important role in chemical reactions.
Overall, the chemical structure of 2-methyl-octahydropyrrolo (3,4-c) pyridine is composed of a saturated dicyclo fused with pyrrole and pyridine, and a methyl group at a specific position. This unique structure determines its special properties and potential applications in the field of organic chemistry.
What are the physical properties of 2-methyl-octahydropyrrolo (3,4-c) pyridine?
2-Methyl-octahydro-pyrrolido (3,4-c) pyridine is an organic compound. It has unique physical properties, and today I will give you a detailed look.
Looking at its properties, under normal temperature and pressure, this compound is mostly colorless to light yellow liquid, clear and transparent, like a clear spring. Its smell is quite special, exuding a faint smell that is different from common substances. It is not pungent and unpleasant, but it is unique, like drawing a different "odor line" in the air.
When it comes to boiling point, the boiling point of this compound is in a specific temperature range, about [X] ° C. This boiling point property allows it to transform from liquid to gaseous under specific temperature conditions. Just like the "command" of the temperature, the substance completes a wonderful "transformation" from liquid form to gas form, and this process follows the guidance of physical laws.
In terms of melting point, its melting point is about [X] ° C. When the temperature drops to the melting point, the compound gradually solidifies from liquid to solid state, just like time solidifies, and the material form freezes frame. This property is of great significance in the storage and transportation of substances.
Solubility is also one of the important physical properties. 2-Methyl-octahydropyrrolido (3,4-c) pyridine exhibits good solubility in organic solvents such as ethanol and ether. As if organic solvents are its "intimate partners", the two can fuse with each other to form a uniform solution system. However, the solubility in water is relatively limited, just like oil and water are difficult to fuse, only a very small amount can be dispersed in water.
In addition, the density is also a manifestation of its physical properties. The density of the compound is about [X] g/cm ³, which is higher or lower than that of water. This density characteristic affects its physical behavior such as floating state in different media.
All of the above physical properties are inherent to 2-methyl-octahydropyrrolido (3,4-c) pyridine, which is like its unique "identity label", giving it a unique "role" in the field of chemistry and related applications.
What are the common uses of 2-methyl-octahydropyrrolo (3,4-c) pyridine?
2 - methyl - octahydropyrrolo (3,4 - c) pyridine is an organic compound, which is commonly used in the field of medicinal chemistry.
It can be used as a key intermediate in drug research and development. Due to its special chemical structure, it can pave the way for the creation of new drug molecules. For example, in the development of drugs for nervous system diseases, this compound can be used as a starting material, and various chemical reactions can be used to construct molecular structures with specific biological activities, which are expected to play a therapeutic role in diseases such as epilepsy and Parkinson's disease. This is because the compound structure can bind to specific receptors on the surface of nerve cells to regulate the transmission of neurotransmitters for therapeutic purposes.
Furthermore, in the field of organic synthesis chemistry, it also plays an important role. As a characteristic structural unit, chemists can carry out a series of complex organic synthesis reactions with their unique reactivity. By modifying and derivatization of its structure, it can create organic compounds with diverse structures, greatly enriching the types of organic compounds, and delivering new substances for materials science, pesticide chemistry and other fields to meet the needs of different fields for special performance compounds.
In addition, in the study of pharmaceutical activity, 2-methyl-octahydropyrrolo (3,4-c) pyridine can be used as a lead compound. By optimizing its structure and measuring the biological activity of the derived compounds, researchers can find drug candidates with better activity and higher selectivity, accelerate the process of new drug development, and contribute to human health and well-being.
What are the synthesis methods of 2-methyl-octahydropyrrolo (3,4-c) pyridine?
The synthesis of 2-methyl-octahydro-pyrrolido [3,4-c] pyridine has been known for a long time. This synthesis method is the essence of chemical technology and involves many chemical changes and steps.
In the past, one of the methods for synthesizing this compound is to start with a specific nitrogen-containing heterocyclic compound as a group. The compound needs to have an appropriate substituent and structure to facilitate subsequent reactions. First, it encounters a specific alkylating agent. This alkylating agent can introduce methyl groups. This process requires precise control of reaction conditions, such as temperature and solvent selection, which are all crucial. If the temperature is too high, side reactions may occur and the product is impure; if the temperature is too low, the reaction will be slow and time-consuming. The nature of the solvent also affects the rate and direction of the reaction. The choice of polar solvent or non-polar solvent depends on the characteristics of the reactants.
Furthermore, when constructing the ring structure of octahydro pyrrolido [3,4-c] pyridine, the condensation reaction is often the main thing. Select an active carbonyl compound and a nitrogen-containing nucleophile, the two meet, and through a series of changes such as condensation and cyclization, they gradually become the target ring system. In this step, the use of catalysts is indispensable, which can accelerate the reaction process and reduce the activation energy required for the reaction. However, the type and amount of catalysts also need to be carefully regulated, and different catalysts have different effects on the selectivity and rate of the reaction.
In addition, there are also those who use natural products as starting materials. Some natural products have a structural framework similar to the target, and can be synthesized by chemical modification and transformation. The beauty of this method is that the structure of natural products is complex and delicate, and the steps of artificial synthesis can be reduced by the creation of nature. However, it may be difficult to obtain natural product raw materials, and its separation and purification also requires complicated methods.
Synthesis of 2-methyl-octahydropyrrole [3,4-c] pyridine There are various methods, and each method has its advantages and disadvantages. Chemists need to weigh and consider according to actual needs, and choose the best method to obtain pure and sufficient products.
Where is 2-methyl-octahydropyrrolo (3,4-c) pyridine used?
2-Methyl-octahydropyrrolido (3,4-c) pyridine, this is an organic compound. It has applications in many fields, let me tell you one by one.
In the field of medicine, it is of great significance. It is a key intermediate in many drug development. Because of its unique chemical structure, it can participate in the construction of molecules with specific pharmacological activities. For example, in the preparation of some nervous system drugs, it can precisely adjust the binding properties of drug molecules to nerve receptors to enhance drug efficacy or reduce side effects. The structure of this compound can give the drug better lipophilicity or hydrophilicity, helping it to pass through the biofilm smoothly and reach the target efficiently.
In the field of materials science, it also has its own influence. It can be used to synthesize polymer materials with special properties. By introducing it into the polymer skeleton, the mechanical properties and thermal stability of the material can be improved. For example, when preparing engineering plastics with good flexibility and high strength, 2-methyl-octahydropyrrolido (3,4-c) pyridine can be used as a structural unit to enhance the interaction between molecules, thereby improving the overall performance of the material.
Furthermore, in the field of organic synthetic chemistry, it is an important synthetic building block. Organic chemists often use it as a starting material to construct more complex organic molecular structures through various chemical reactions, such as nucleophilic substitution and addition reactions. It is like the cornerstone of building a molecular edifice, providing rich possibilities for the synthesis of new organic compounds, enabling chemists to explore compounds with novel structures and functions.
